Project Details
Harnessing the potato-microbiome interactions for development of sustainable breeding and production strategies
Applicants
Dr. Joachim Kopka, since 9/2020; Professor Dr. Michael Schloter
Subject Area
Plant Breeding and Plant Pathology
Term
from 2019 to 2023
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 420528765
Current conventional agriculture relies heavily on high nutrient inputs that will be taken up directly by the plants as well as massive plant protection using a large number of pesticides. In these systems, plants are considered as sole players, disregarding plant traits that can improve the recruitment of beneficial soil microbes for nutrient mobilization and plant protection. As a consequence, conventional practices have resulted in low nutrient use efficiencies, groundwater pollution and increased soil erosion to non-sustainable levels. High loads of synthetic and organic fertilizers as well as synthetic pesticides have made many beneficial soil biota, especially microbes, redundant. Their multifunctional ecosystem services have been replaced with single-purpose synthetic additives designed to support and protect plants directly, and their interactions with the plant have been neglected in breeding strategies. The concept of this project relies on the principle that plants naturally interact with beneficial (soil) microbes, making them less dependent on synthetic inputs. For instance, varieties with increased root biomass and carbon exudation should be able to recruit beneficial soil microbiota more efficiently than conventional varieties, selected to work alone and on high nutrient availability. The greater the belowground diversity in the soil, the better the prospects of plant roots to recruit beneficial microbes to mobilize nutrients, reduce stresses and suppress pathogens. Nutrient use efficiency increases with improved microbial nutrient recruitment alongside a reduced fertilizer dependency and lowered groundwater pollution. This approach will be particularly beneficial for potato cultivation where many varieties have underdeveloped root systems and are susceptible to pests and other environmental stress factors including changes in climate.PotatoMETAbiome aims at identifying potato genotypes that interact effectively with the soil microbiome, thus generating cultivars that have reduced dependencies on external inputs (synthetic fertilizers and pesticides) while maintaining high yield, under non-stress as well as biotic (pathogen pressure) and abiotic stress conditions. Potato varieties will be selected for microbiome-interactive traits (MIT) and analysed for both plant and microbiome genomics, thus identifying the mechanisms controlling the positive effect of the microbiome and genetic markers associated with MIT for use in future potato breeding strategies.
DFG Programme
Research Grants
International Connection
Austria, France, Ireland, Netherlands, Poland
Cooperation Partners
Dr. Eleonore Atard; Professorin Dr. Gabriele Berg; Professorin Dr. Joana Falcao-Salles; Professorin Dr. Magdalena Frac; Dr. Mariusz Maciejczak; Dr. Achim Schmalenberger; Dr. Krzysztof Treder
Ehemaliger Antragsteller
Privatdozent Dr. Dirk Hincha, until 9/2020 (†)